转植酸酶基因家蚕的制作及表达检测

家蚕Bombyx mori丝腺具有高效合成蛋白质的特性,开发在丝腺特异表达外源蛋白质的生物反应器具有重要的意义。本研究利用piggyBac来源的两种载体pPIGA3GFP和pBac{3×P3-EGFPaf},建立了稳定的家蚕转基因技术体系; 然后,利用一株黑曲霉来源的植酸酶基因,构建了在家蚕后部丝腺特异表达的融合表达载体pBac [3×P3-EGFP+ FibLphyADsRed],注射蚕卵后,在53个G1蛾区中检测到3个有荧光蚕的蛾区。经Southern blot和反向PCR验证,转基因表达盒整合到家蚕染色体上。RT-PCR结果显示,植酸酶基因特异性地在后部丝腺表达,其表达模式与家蚕轻链丝素基因一致。结果表明我们成功获得了在后部丝腺特异表达植酸酶融合蛋白的转基因蚕,这为进一步开发家蚕生物反应器,利用转基因蚕生产各种重组蛋白具有积极的促进作用。     

Generation of transgenic silkworms for production of erythropoietin in Bombyx mori

There have been many attempts to generate various essential proteins using transformed E. coli systems. However, prokaryote systems are not equipped with the protein maturation mechanisms necessary to generate eukaryotic proteins. In this sense, among the eukaryotes, silkworms have major merits in overcoming the difficulties. Such protein maturation mechanisms are available in silkworms. In this study, a transgenic silkworm producing rhEPO in the cocoon was generated and purified. Specifically, we constructed a transgenic silkworm using a vector system that could be controlled to the next generation. To accomplish this, we microinjected the system into eggs laid during the preblastoderm stage. The rhEPO was then purified from transgenic silkworm cocoons using a Con A affinity column. The biological activity of rhEPO isolated from the cocoon of transgenic silkworms was then assessed in a cell culture system using an EPO-dependent cell line, F-36E. Next, PCR analysis was used to demonstrate that stable gene expression can occur in the embryos of the silkworm, Bombyx. mori. Transgenic silkworms were then selected and observed to ensure that the transgenic silkworm was maintained and transmitted to their progeny. The rhEPO was subsequently purified from the transgenic silkworm cocoon and the electrophoretic pattern of the purified rhEPO revealed a protein band with a molecular weight of approximately 20 kDa. A total of 3 mg of rhEPO was eluted from 10 g of cocoons. The proliferation of F36E cells for 25 ng/ml rhEPO was 1.32, while the proliferation for 2.5 IU/ml hEPO was 1.32. The proliferation of these cells could be induced by commercial hEPO, as well as by rhEPO from transgenic silkworm cocoons. An in vivo test of mice treated with rhEPO revealed relatively high RBC values when compared to normal mice. These results indicated that purified glycosylated EPO from transgenic silkworms had biological activities. Overall, the transgenic silkworm technique will be very useful for the large scale production of proteins for diagnostic and therapeutic purposes.     

Production of an active feline interferon in the cocoon of transgenic silkworms using the fibroin H-chain expression system

We constructed the fibroin H-chain expression system to produce recombinant proteins in the cocoon of transgenic silkworms. Feline interferon (FeIFN) was used for production and to assess the quality of the product. Two types of FeIFN fusion protein, each with N- and C-terminal sequences of the fibroin H-chain, were designed to be secreted into the lumen of the posterior silk glands. The expression of the FeIFN/H-chain fusion gene was regulated by the fibroin H-chain promoter domain. The transgenic silkworms introduced these constructs with the piggyBac transposon-derived vector, which produced the normal sized cocoons containing each FeIFN/H-chain fusion protein. Although the native-protein produced by transgenic silkworms have almost no antiviral activity, the proteins after the treatment with PreScission protease to eliminate fibroin H-chain derived N- and C-terminal sequences from the products, had very high antiviral activity. This H-chain expression system, using transgenic silkworms, could be an alternative method to produce an active recombinant protein and silk-based biomaterials.     

Transgenic silkworms secrete the recombinant glycosylated MRJP1 protein of Chinese honeybee, <Emphasis Type="Italic">Apis cerana cerana</Emphasis>

Major royal jelly protein-1 (MRJP1) is the most abundant glycoprotein of royal jelly (RJ) and is considered a potential component of functional foods. In this study, we used silkworm transgenic technology to obtain five transgenic silkworm lineages expressing the exogenous recombinant Chinese honeybee, Apis cerana cerana, protein-1 (rAccMRJP1) under the control of a fibroin light chain (Fib-L) promoter in the posterior silk glands. The protein was successfully secreted into cocoons; specifically, the highest rAccMRJP1 protein content was 0.78% of the dried cocoons. Our results confirmed that the protein band of the exogenous rAccMRJP1 protein expressed in the transgenic silkworm lineages was a glycosylated protein. Therefore, this rAccMRJP1 protein could be used as an alternative standard protein sample to measure the freshness of RJ. Moreover, we also found that the overall trend between the expression of the endogenous and exogenous genes was that the expression level of the endogenous Fib-L gene declined as the expression of the exogenous rAccMRJP1 gene increased in the transgenic silkworm lineages. Thus, by employing genome editing technology to reduce silk protein expression levels, a silkworm bioreactor expression system could be developed as a highly successful system for producing various valuable heterologous proteins, potentially broadening the applications of the silkworm.     

Transgenic silkworms produce recombinant human type III procollagen in cocoons

We describe the generation of transgenic silkworms that produce cocoons containing recombinant human collagen. A fusion cDNA was constructed encoding a protein that incorporated a human type III procollagen mini-chain with C-propeptide deleted, a fibroin light chain (L-chain), and an enhanced green fluorescent protein (EGFP). This cDNA was ligated downstream of the fibroin L-chain promoter and inserted into a piggyBac vector. Silkworm eggs were injected with the vectors, producing worms displaying EGFP fluorescence in their silk glands. The cocoons emitted EGFP fluorescence, indicating that the promoter and fibroin L-chain cDNAs directed the synthesized products to be secreted into cocoons. The presence of fusion proteins in cocoons was demonstrated by immunoblotting, collagenase-sensitivity tests, and amino acid sequencing. The fusion proteins from cocoons were purified to a single electrophoretic band. This study demonstrates the viability of transgenic silkworms as a tool for producing useful proteins in bulk.     

Production of scFv-conjugated affinity silk powder by transgenic silkworm technology

Bombyx mori (silkworm) silk proteins are being utilized as unique biomaterials for medical applications. Chemical modification or post-conjugation of bioactive ligands expand the applicability of silk proteins; however, the processes are elaborate and costly. In this study, we used transgenic silkworm technology to develop single-chain variable fragment (scFv)-conjugated silk fibroin. The cocoons of the transgenic silkworm contain fibroin L-chain linked with scFv as a fusion protein. After dissolving the cocoons in lithium bromide, the silk solution was dialyzed, concentrated, freeze-dried, and crushed into powder. Immunoprecipitation analyses demonstrate that the scFv domain retains its specific binding activity to the target molecule after multiple processing steps. These results strongly suggest the promise of scFv-conjugated silk fibroin as an alternative affinity reagent, which can be manufactured using transgenic silkworm technology at lower cost than traditional affinity carriers.     

Expression of the Japanese oak silkworm Antheraea yamamai fibroin gene in the domesticated silkworm Bombyx mori

Abstract To understand the evolutionary conservation of the gene expression mechanism and secretion machinery between Antheraea and Bombyx fibroins, we introduced the genomic A. yamamai fibroin gene into the domesticated silkworm, B. mori. The spliced A. yamamai fibroin mRNA appeared only in the posterior region of the silk gland of the transgenic silkworm, suggesting that the functions of the fibroin promoter region and the splicing machinery are conserved between these two species. The A. yamamai fibroin protein was detected in the lumen of the silk gland of the transgenic silkworm, albeit at lower levels compared with the B. mori‐type fibroin. We found a strong degeneration of the posterior region of the silk gland of the transgenic silkworm. As a result, the cocoon shell weight was much lower in the transgenic silkworm than in the non‐transgenic line. These results indicate that the promoter function and splicing machinery are well conserved between A. yamamai and B. mori but that the secretion mechanism of fibroin is diversified between the two.     

High-Toughness Silk Produced by a Transgenic Silkworm Expressing Spider (Araneus ventricosus) Dragline Silk Protein

Spider dragline silk is a natural fiber that has excellent tensile properties; however, it is difficult to produce artificially as a long, strong fiber. Here, the spider (Araneus ventricosus) dragline protein gene was cloned and a transgenic silkworm was generated, that expressed the fusion protein of the fibroin heavy chain and spider dragline protein in cocoon silk. The spider silk protein content ranged from 0.37 to 0.61% w/w (1.4–2.4 mol%) native silkworm fibroin. Using a good silk-producing strain, C515, as the transgenic silkworm can make the raw silk from its cocoons for the first time. The tensile characteristics (toughness) of the raw silk improved by 53% after the introduction of spider dragline silk protein; the improvement depended on the quantity of the expressed spider dragline protein. To demonstrate the commercial feasibility for machine reeling, weaving, and sewing, we used the transgenic spider silk to weave a vest and scarf; this was the first application of spider silk fibers from transgenic silkworms.     

A new method for the modification of fibroin heavy chain protein in the transgenic silkworm

We constructed a new plasmid vector for the production of a modified silk fibroin heavy chain protein (H-chain) in the transgenic silkworm. The plasmid (pHC-null) contained the promoter and the 3' region of a gene encoding the H-chain and the coding regions for the N-terminal domain and the C-terminal domain of the H-chain. For the model protein, we cloned a foreign gene that encoded EGFP between the N-terminal domain and the C-terminal domain in pHC-null and generated transgenic silkworms that produced a modified H-chain, HC-EGFP. Transgenic silkworms produced HC-EGFP in the posterior part of silk gland cells, secreted it into the lumen of the gland, and produced a cocoon with HC-EGFP as part of the fibroin proteins. N-terminal sequencing of HC-EGFP localized the signal sequence cleavage site to between positions A((21)) and N((22)). These results indicate that our new plasmid successfully produced the modified H-chain in a transgenic silkworm.     

Expression of the hGM-CSF in the silk glands of germline of gene-targeted silkworm

To express human granulocyte-macrophage colony-stimulating factor (hGM-CSF) gene in the silk glands of transformation silkworm (Bombyx mori) based on gene-targeting, two fragments from fibroin heavy chain gene (fib-H) of silkworm were cloned and sequenced. One fragment contains the 1st exon and its downstream 1st intron’s partial sequence; and the other fragment contains the 1st intron’s partial sequence and the 2nd exon’s partial sequence. Then the two fragments, as homologous arm, were inserted into pSK to generate a gene-targeted vector, pSK-HL-A3GFP-FLP-GM-CSF-FLPA-HR in which a gfp gene driven by A3 promoter and an hGM-CSF gene under the control of fibroin light chain (fib-L) promoter were included. The vector was transferred into the silkworm eggs using sperm-mediated gene transfer. After being screened for green fluorescent, the transformation silkworm was obtained, whose genome was verified by PCR and dot hybridization to confirm whether the target genes had been integrated into the silkworm genome. Furthermore, in the posterior silk glands of the G4 generation transformation silkworms, a specific band with the molecular weight of 22 kDa could be detected by Western blotting with an antibody against hGM-CSF, and the expression level of the hGM-CSF estimated by ELISA was approximately 1.26 ng per gram fresh posterior silk gland.     

Generation of a transgenic silkworm that secretes recombinant proteins in the sericin layer of cocoon: production of recombinant human serum albumin

In this study we produced germline transgenic silkworms that spin cocoons containing recombinant human serum albumin (rHSA) in the sericin layer. A piggyBac-based transformation vector was constructed that carried HSA cDNA driven by sericin-1 gene promoter, viral enhancer hr3, and gene encoding viral trans-activator IE1. Isolated silk glands were bombarded with the vector and transplanted into host larvae. Three days later, the transplants were immunohistochemically analyzed, which showed that middle silk gland (MSG) cells expressed rHSA and secreted it into the MSG lumen. Then, silkworm eggs were injected with the vector and developed to larvae. The obtained transgenic silkworms spun silk threads whose sericin layers contained rHSA at 3.0microg/mg of cocoons. Most (83%) of the rHSA in cocoons was extracted with phosphate buffered saline, which was then subjected to ammonium sulfate precipitation and affinity chromatography. Finally, we obtained 2.8mg of 99%-pure rHSA from 2g of cocoons. Measurements of circular dichroism spectra of rHSA, and equilibrium dissociation constants of rHSA to warfarin and naproxen indicated that rHSA was conformationally and functionally identical to natural plasma HSA. Germline transgenic silkworms will be useful for producing various recombinant proteins in the sericin layer of cocoons.     

Germ line transformation of the silkworm, <Emphasis Type="Italic">Bombyx mori</Emphasis>, using the transposable element <Emphasis Type="Italic">Minos</Emphasis>

We investigated the use of Minos as a vector for transgenesis in the silkworm, Bombyx mori. We first constructed a vector plasmid with the green fluorescent protein (GFP) gene fused with the silkworm cytoplasmic actin gene (A3) promoter, and a helper plasmid with the Minos transposase gene controlled by the same A3 promoter. Injection of the vector and helper plasmid DNA into silkworm eggs produced transgenic animals in the following generation. The efficiency of transgenic silkworm production using this method was much lower than that obtained using piggyBac-mediated germ line transformation. However, >40-fold increase in the efficiency of producing transgenic silkworms was obtained using an in vitro synthesized source of Minos transposase mRNA. We conclude that the Minos transposon is a useful vector for construction of transgenic silkworms, particularly when in vitro synthesized mRNA is used. This is the first report showing that Minos can be used as a vector for germ-line transformation in lepidopteran insects.     

带有丝素重链信号肽序列的家蚕丝胶蛋白启动子驱动DsRed的瞬时分泌表达

为了探讨家蚕Bombyx mori丝素蛋白重链信号肽序列在中部丝腺组织中是否具有功能活性,根据家蚕丝蛋白基因的启动子活性高、丝蛋白具有高效分泌的特性,构建了带有丝素重链基因fib-H信号肽的家蚕丝胶-1(ser-1)启动子(ser-HS),用ser-HS驱动DsRed基因构建了分泌型瞬时表达载体pSK-SerHS-DsRed-polyA。转染细胞实验显示,该载体能在家蚕BmN细胞中瞬时表达DsRed。家蚕注射载体后,可在中部丝腺腔中检测到红色荧光,表明瞬时表达的DsRed已分泌到丝腺腔内。据此提出克隆的fib-H信号肽序列在家蚕中部丝腺组织中具有信号肽的功能。     

LIM-homeodomain transcription factor Awh is a key component activating all three fibroin genes,fibH, fibL and fhx,in the silk gland of the silkworm,Bombyx mori

In the silkworm Bombyx mori, three fibroin genes, fibroin-heavy-chain (fibH), fibroin-light-chain (fibL) and fibrohexamerin (fhx), are coexpressed only in the posterior silk gland (PSG) cells, while the sericin genes encoding silk glue proteins are expressed in the middle silk gland (MSG) cells. Silk gland factor-2 (SGF-2) is a PSG-specific activator complex of fibH, composed of a LIM-homeodomain protein, Awh, and its cofactors, Ldb and Lcaf. We investigated whether SGF-2 can activate other fibroin genes using transgenic silkworms. The genes for Ldb and Lcaf were expressed ubiquitously in various tissues, while the gene for Awh was expressed strictly specific in PSG of the wild type silkworms. Misexpression of Awh in transgenic silkworms induced ectopic expression of fibL and fhx as well as fibH in MSG. Coincidently with the induction of fibL and fhx by Awh, binding of SGF-2 to the promoter of fibL and fhx was detected in vitro, and SGF-2 binds directly to the fhx core promoter. Ectopic expression of the fibroin genes was observed at high levels in the middle part of MSG. Moreover, fibL and fhx were induced in the anterior silk gland (ASG) of the transgenic silkworms, but fibH was not. These results indicate that Awh is a key activator of all three fibroin genes, and the activity is probably regulated in conjunction with additional factors.     

家蚕丝素蛋白轻链基因（fib-L）启动子序列的克隆及其活性分析

家蚕Bombyx mori丝素蛋白轻链（fibroin light-chain, fib-L）基因fib-L具有在后部丝腺组织专一性、高效性表达的特点。为了利用其启动子构建能够表达外源基因的丝腺生物工厂,本实验对fib-L启动子活性进行了研究。通过PCR法克隆了fib-L启动子元件,序列分析显示fib-L启动子由位于-33 ～ -25处的TATA盒元件和位于－128～－121处的特征性序列GTCAATTT共同组成。用fib-L启动子控制报告基因DsRed进行家蚕BmN细胞和蚕体内的瞬时表达研究,结果表明fib-L启动子可以驱动DsRed报告基因在BmN细胞和家蚕后部丝腺组织中瞬时表达。